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Transcript of EXPLORATIONS AND EXPERIMENTS IN PHYSICS LAB … · EXPLORATIONS AND EXPERIMENTS IN PHYSICS LAB...
EXPLORATIONS AND
EXPERIMENTS IN PHYSICS
LAB MANUAL FOR PHYSICS 102
August, 2003
J. Franz
F.B. Seeley
Victor Zhan
Physics Department
University of Alabama in Huntsville
INTRODUCTION TO THE PHYSICS 102 LABORATORY
Goals:
The goals of the lab are twofold: (1) for you to see and experience physics at a
hands-on level and (2) for you to learn how to use the experimental method to reach
conclusions. To accomplish these goals, each week you will make some measurements
using specialized lab equipment and then analyze your results. There are two types of
activities included in this manual: explorations and experiments.
The explorations are more qualitative, and in many cases, the exploration is done
before the topic is covered in lecture. This is intended to give you some direct experience
with the phenomena so the lecture will be easier to understand. The experiments are
intended to give you practice in making quantitative measurements and using these to
deduce some physical-mathematical relationships.
Supplies:
In addition to this lab manual, you will need the following materials in lab:
Calculator
Notebook with crosshatched pages for graphing
12 " ruler
Ball-point pen
1-2 colored pens or pencils
Pre-Lab Preparation:
All of your experimental work will be carried out during the 2-hour lab period.
Also, your lab reports could be written and turned in during that same time period, but
you will need to prepare ahead of time. Read over the experiment or exploration before
you come to lab and try to understand what you will be doing. Review any material in
your textbook that you think will be useful.
Lab Reports:
Your reports should have the character of a scientific notebook. Using any of
reports, you or someone else should be able to reproduce your work. The cornerstone of
the experimental method is the ability to repeat the method and get the same results. This
can only be done if the experimental work is recorded clearly. You can assume that
anyone trying to repeat your experiments will have the same lab manual you have, so you
don't have to copy procedures and theory that are included in the manual.
Record your work in ink. Cross out mistakes with a single line to be legible. Keep
a record of all you do. Never, never record data on scratch paper and then recopy into
your notebook. Extreme neatness is not required when writing the reports during the lab
period.
Your lab report (i.e. notebook) should contain the following parts (not necessarily
in this exact order):
Title and Partners name
Introduction...a sentence or two that describes the main purpose
Data...concise, readable form including units. Use tabular format. Estimate
uncertainties of each measurement.
Analysis...this includes any calculations and graphing of the data
Results and Conclusions...This should include a discussion of the results
obtained and a brief summary of what you have learned from the experiment. You should
also answer any discussion questions posed in the experiment, discuss possible sources of
error, and record any special insights you have gained. Your conclusions should
demonstrate your understanding of the physics concepts involved in the experiment.
Grading:
Your lab report will be graded based on the components listed above. If any of the
parts are omitted or poorly done, your instructor will lower your grade and write a brief
comment pointing out what is wrong.
It is natural for students and partners to talk to each other and use the same data.
Your analysis, graphs and discussion should be your own. Reports that are identical to
each other will be downgraded.
Each lab instructor has office hours. Find out where and when in case you need to
see him or her out of class.
EXPERIMENTS IN PHYSICS
A lab Manual for Physics 102
UAH
August 2003
CONTENTS
Introduction to the Laboratory
Lab activities
1. Electric Charge, Field and Potential 1
2. Electrostatic Charge, Potential and Capacitance 6
3. Circuit Basics 12
4. Electric Voltage, Current, Power and Work 16
5. Magnetic Field 21
6. Magnetism and Tangent Galvanometer 24
7. Induced EMF 28
8. Reflection and Refraction of Light 31
9. Lenses & Optical Instruments 36
10. Physical Optics 39
11. Atomic Spectra 45
12. Photoelectric Effect 50
Appendices
A-1 Graphical Presentation of Data
A-2 Summary of Error Analysis
1
ELECTRIC CHARGE, ELECTRIC FIELD
AND ELECTRIC POTENTIAL
INTRODUCTION:
This lab activity is an exploration of the concepts of:
1. Electric Charge,
2. Electric Field and Field Lines,
3. Electric Potential.
You will use a computer software program that graphically plots the E-field lines,
field vectors Er
, and potentials that are all used to visualize what occurs in the regions
surrounding arrangements of points of electric charges.
CONCEPTS:
First, let’s briefly review these concepts and definitions.
Electric Charge… + and –
There are two types of electrical charges, positive and negative. We know that the
negative or minus charge is the property of the electron. A surplus of electrons makes a
body negative. The proton in the nucleus of an atom carries the positive charge.
Removing electrons from a material (a deficiency of electrons) makes the material
positive. How do you know that an electric charge exists? One way is by the forces they
exert on one another.
Force Between Point Charges… 2
21
r
qqkF = [Coulombs Law]
The force between two sets of point charges is directly proportional to the amount
of charge on each, i.e. 1q and
2q . The force is also inversely proportional to the square of
the distance between them. Note that the force can be either attractive or repulsive.
As more and more charge is added to different places, the calculations of the
forces gets complicated but basically is a vector summation of all the individual charges.
Electric Field… 2q
FE
rr=
The concept of an electric field surrounding an electric charge is analogous to the
gravitational field surrounding a mass. A single point with an electrical charge of amount
1q can be thought of as creating an electric fieldE
r that surrounds the space around it. If
another point charge, 2q , is placed somewhere in the “E
r field”, this second charge
experiences a force that is equal to EqFrr
2= . Both F
r and E
r are vector quantities that
have a direction as a magnitude. When you have a collection of point charges, there is an
2
electric field that is the vector summation of the electric fields from all the individual
point charges.
Electric Field Lines…
These are drawn to show the “direction” of the electric field, Er
. The field line
starts on “+” charges and end on “-” charges. By definition, the Er
field vectors are all
tangent to the field lines. However, the strength of Er
[length of the vector] depends on
the distance from the charge.
Electric Potential…
Electric potential is a concept related to “work”. Specifically, it’s about how much
“work” is done on moving an electric charge around in the electric field. Again, this is
analogous to moving a small mass around in the earth’ gravitational field, with the added
complication that the charge and field are both positive and negative. We can write the
equation for the work [force times distance] done on a charge 2q as,
SdEqSdFwrrrr
⋅=⋅=2
Notice that if you move the charge perpendicular to the Er
field, no work is done. That is
an “equipotential path”. Work and energy are of course referenced from some arbitrary
starting point. In electrostatics, one measures or computes the amount of work in moving
a test charge, 2q from infinity to some position on the E
r-field.
Potential Difference…
A related concept is potential difference; this is the amount of work done to move
a test charge between any two points in the Er
-field.
OBJECTIVES and APPARATUS:
You’ll use a computer simulation program, the “EM Field”. We want you to use
this program to draw field vector Er
, field lines and equipotential lines for several
different arrangements of charges. As a minimum, you’ll look at
a. single charges, both plus and minus,
b. pairs of charges, and
c. two lines of several charges.
3
PROCEDURE:
Part I. A Single point Charge
1. Double click icon “EM Field” to open the EM Field program window.
2. Click “Sources” in the menu bar. And select 3D point charges.
3. Click Display menu, and select show grid.
4. Drag a “+ 1” charge near the center of the display.
5. To see the electric field, Er
, go to the “Field and Potential” menu and choose
“Field Vectors”. Then, click on the screen. You’ll see an arrow drawn that
represents the Er
-field. The direction of the arrow is the direction of the field.
The length of the arrow is the relative magnitude of the Er
-field. Try placing
or “clicking” at four different distances from the charge, 1 unit. 0.5 units, 2
units and 3 units.
Questions: With a positive (+ 1) charge, which direction are the Er
-field vectors?
Does the Er
-field vary inversely with the distance from the single charge? Record
the relative lengths of each to compare with other values of charge.
6. Next, try dragging off the + 1 and replace with – 1 charge.
Question: What happened to the direction of the Er
-field?
7. Replace with + 2 charge. Again, note the relative lengths of the Er
-field.
Question: Now what happened to the magnitude of the field relative to + 1
charge?
8. Try another “Field and Potential” option by selecting “Field Lines”. Then
click the screen at points near your Er
-field vectors.
Question: Are the field lines and field vectors tangent? So, what do the field lines
indicate?
Part II. Two Point Charges
Next, you can simulate the more interesting case of two charges.
First, Clean up Screen by selecting this option in the “display” menu.
4
1. Drag up an additional charge two units away from the first. To begin, make
one a +1 charge and other –1 charge. Then, draw 4 or 5 field lines.
2. Finally, draw several Er
-field vectors along the field lines. Make a sketch or
print out of a display that you can discuss in your report.
Questions: In which general direction does Er
-field vector point? If a small test
(positive) charge were placed at that position in the Er
-field, in which direction
would it move? Would this test charge always move in direction of the field lines?
(Assuming that it had zero initial velocity.)
3. Click on the Er
-field precisely _ way between two equal charges.
Question: Assuming that you could find the precise _ position, what would the
magnitude of the Er
-field vector be?
Part III. Two Charged Plates
Select “Get charges or currents from file” from the File menu, and then open the
file “qplates.emf”. This adds two rows of charged rods that approximate a pair of charged
plates.
1. Draw a several field lines that will connect points at the center and at the ends
of this “plate”.
2. Also, draw in the Er
-field vectors tangent at several places to one of the field
lines.
Questions: Describe the motion of a positive test charge released near the center
of the plate? … near the end of the plate? …outside the plates?
Part IV. Electric Potentials
1. Get out of “qplates.emf” by clicking the Source menu, and then select “3D
point charge”. Add charge, +4.
2. Draw in several field lines.
3. Next select “Equipotentials with number” from “Field and Potential” menu.
Draw the equipotential lines at several distances from the charge; say 1, 2, 4
and 8 units away. Note that a “number” is displayed next to each equipotential
line.
5
Questions: What are the relative directions of the field lines and the equipotential
lines?
4. Try “dragging” a Er
-field vector along the equipotential line.
Questions: Did the magnitude of the Er
-field change? Describe the direction of
the Er
-field as you moved along the equipotential line? Explain why no work
would have been done on the charge as you moved it along this equipotential
line?
5. Next place clicks a Er
-field vector on each of the 4 equipotential lines.
Questions: Describe the relative magnitude of each Er
vector? Is work required
to move from one equipotential line to the next? Explain.
What do the “numbers” on the equipotential lines mean? Do an approximate
numerical calculation to show how much work is done on moving a +1 charge
from a large distance to four of your equipotential lines.
6
ELECTROSTATIC CHARGE, POTENTIAL AND CAPACITANCE
OBJECTIVE:
By doing this experiment, we want you to acquaint yourself with the following
concepts:
Electric charge
Electric potential
Capacitance
METHOD:
In this experiment you’ll use a glass rod and silk cloth to produce a positive
charge on the rod. Then you will use a rubber or plastic rod and wool cloth to produce a
negative charge on the second rod. You’ll be able to demonstrate the forces of attraction
and repulsion between charges.
We’ll also show you how to use an electrometer to measure the electrical
potential (measured in volts) between two conducting surfaces when electrical charges
are produced on those surfaces.
You’ll also investigate capacitance by adding charge to parallel plate capacitor
and measuring the relationship between charge and potential.
THEORY and DEFINITIONS:
Before starting the procedure, you should review the definitions of charge,
electrical potential and capacitance given at the end of this write up.
APPARATUS:
Rubber or Phenolic Rod and Wool Cloth, Glass Rod and Silk Cloth, String, Pith
Ball, Lab Stand, Electrometer, Ceramic Spacer, Parallel Plate Capacitor, Ruler and
Vernier Caliper.
PROCEDURE:
Part 1.
Note: Throughout this experiment, you’ll need to remove excess charge from your
body and the apparatus. Do this by touching the apparatus with one hand and the water
pipe or other “ground” with the other hand.
1. Generate a charge by rubbing the rubber rod with the wool cloth. Then
transfer this charge to the suspended pith ball by touching it with the rod.
Describe what happened when you initially brought the rod close to the ball.
Was it attracted or repelled?
7
2. Now generate more charge on the rubber rod. This time slowly move it close
to the ball. What happened? Why?
3. Repeat steps 1-2 using the glass rod and silk cloth. [first discharge the ball by
touching it and the water pipe or ground]
4. After charging the ball with the glass rod, try bringing the charged rubber rod
slowly toward the previously charged ball. Do the charges from the rubber rod
appear to be different from those on the glass rod? Explain this.
Part 2.
1. Assemble a parallel plate capacitor. Use the two aluminum plates and separate
them by the thickness of two ceramic spacers.
2. Connect the wire from the electrometer to the capacitor as shown. Be sure to
connect the connector with red marking to the top plate. Now any charge on
the top plate will be indicated by the electrometer.
electrometer
spacers red (+)
air
black (-)
capacitor ground
3. Next, ground the plates with your hand to remove any excess charge. Transfer
some charge from the rubber rod to the pith ball. Then suspend the ball over
the top plate and observe the polarity (+ or -) of the electrometer reading.
Actually touch the ball to the plate and record this reading. Was the charge on
the rubber rod positive or negative? Explain your results.
4. Repeat with glass and silk.
5. Return to the rubber rod and wool. This time rub the two together but now
touch the wool cloth to the top plate. How does this with your results in (3.)?
Is this what you would expect? Why?
8
Part 3.
In this part of the experiment, we want you to calculate the amount of charge (and
number of electrons) that you generate and transfer to the capacitor.
You’ll use the equation
Q = CV (1)
where C = the capacitance in farads
and V = the electrical potential difference between the plates in volts
and Q = the charge in coulombs
What the above equation says is that for a given number of volts between the
plates, with a larger the capacitance more charge can be stored on the plates!
So what value do you use for the capacitance of the plates? Use the equation,
C = d
A0ε
(2)
where 0ε = the permittivity of air = mF /109.8
12−×
A = the area of one of the plates
and d = the separation of the plates.
This equation will give you capacitance of the parallel plates alone. The electrometer and
its cable also can store some charge, so it has an effective capacitance, which happens to
be 100 picofarads. That is, F12
10100−
× . Just add the 100 picofarads to the value you
calculate from equation (2). Then use this total capacitance when you’re asked to use
equation (1).
1. Make sure that the capacitor is assembled with two spacers. The thickness of a
spacer is 1.6 mm, then d = 3.2 mm = 3102.3
−× m.
2. Connect the electrometer to the capacitor.
3. Generate some charge using the rubber rod and wool cloth and transfer this to
the top plate.
4. Repeat as often as necessary to get approximately – 100 volts.
5. Now calculate
a. the capacitance of the parallel plates [equation (2)]
b. add 100 picofarads to this answer
c. calculate the total charge on the capacitor and electrometer [equation (1)]
9
d. Using the value for the charge of one single electrons, C19
106.1−
× ,
calculate the number of electrons that you transferred to the capacitor and
electrometer.
EXPLORATON: Electrical potential (volts) and work
In this short exploration, we want you to observe what happens to the
electrometer reading when the separation is varied between two charged parallel plates.
Your instructor will assist you with this exploration when you’re ready.
1. The electrometer should be already connected to the plates of the variable
space capacitor.
2. Charge one plate with a rubber rod and note the electrometer reading. At this
point, answer this question, will there be attraction or repulsion between the
two plates?
3. Slowly increase the distance between the plates and note the electrometer
reading. Did it increase, i.e. become more negative?
4. If the force between the plates was attractive, did you do work on the plates to
overcome this attraction?
5. Push the plates closer together until you are at the original separation. Observe
the electrometer reading.
This brief demonstration should help you later when you study the meaning of
voltage and electrical potential. It is a demonstration of the work done when
charges are moved.
Charge
We now know that charge is a measure of the number of electrical pieces of
matter. The unit of charge is “coulomb”. Benjamin Franklin discovered that there were
two types of electrical charges. He arbitrarily called one type of charge “positive” and the
other type “negative”. But it wasn’t until over 100 years after Ben Franklin that physicists
discovered that atomic matter consisted of electrons (negative charges), protons (positive
charges) and neutrons (no charge). It became clear that practical applications of
electricity usually involve either a surplus or a deficiency of electrons on a surface or the
movement of electrons in metallic conductors. By the time the “electron” was discovered,
theories and applications of electricity had already been developed for some time, so it
was convenient to keep on using Franklin’s conventions for positive and negative
charges. One such convention is about charge flow moving from positive to negative
10
potential. Because the electron is a negative piece of matter, when you add electrons to a
surface, it becomes negative. If you remove electrons, then the surface becomes positive.
Both the proton and the electron have the same absolute value of charge; but the proton is
positive and the electron is negative.
Electrical Potential
Electrical potential is measured in units of volts. The potential difference or
voltage between two points in space is proportional to the amount of work done in
moving charges from one place to another. More precisely, voltage is the number of
joules of work done in moving 1 coulomb of charge. Work has to be done because the
attractive (or repulsive) force between charges must be overcome if the charges are
moved.
Capacitance
Capacitance is measure of the ability of surface to hold charge for a given
electrical potential difference between them. An important equation is Q = CV.
11
Suggest Data Sheet
Part 3.
d = _________ (m) A = _____________ (m2)
C = d
A0ε
= = _________ (F)
Total Capacitance = C + 1210100
−× = = ___________ (F)
Total Charge Q = CV = ___________ (C)
The number of electrons = 19
106.1−
×
Q =
12
CIRCUIT BASICS
INTROGUCTION:
This activity is an exploration of the basic features of electrical circuits.
OBJECTIVE:
As you do this exploration, you’ll acquaint yourself with
complete circuits electrical resistance
series connections parallel connections
METHOD:
In the experiment on electrostatics, we defined and discussed charge and
potential. In this week’s experiment the charge will move continuously through a
complete circuit. This flow of charge past a point in circuit is called electrical current.
Very often people will just speak of current when it is clear that they are talking about
electricity.
The unit of [electrical] current is the ampere (A). An ampere is one coulomb of
charge moving past a point in circuit each second. The direction of the flow is in the
direction taken by a positive charge. This is the convention originated by Benjamin
Franklin.
Another important concept to understand is that of [electrical] resistance. As the
electrons move through a solid material, they will collide with atoms that make up the
solid. As these collisions occur, energy is usually lost by the electrons. [Note; the
electrons only lose energy in this process. The same number of electrons still exists and
continues on through the material.] This energy lost by the electrons is converted to
heating up the material. The material is said to resist the flow of charge, or have electrical
resistance. Some materials like metals, e.g. gold, silver, copper, and aluminum are good
conductors at normal temperatures. Others like carbon, tungsten, and certain alloys and
ceramics offer more resistance to the electrical current and therefore heat up. This heating
is useful, for example, if you want to heat water or light a bulb!
The unit of electrical resistance is the ohm (Ω). When 1 ampere flows in a circuit
and the electrical potential between two points in the circuit is 1 volt, the resistance
between those points is 1 ohm. In general, R is given by
I
VR =
APPARATUS:
Bulbs, Bulb Socket, Battery, Resistor, Rheostat, Voltmeter, Ammeter, and
Connect Wires.
13
PROCEDUE:
1. Take a battery, a light bulb, and one piece of wire. Can you make the bulb
light up? When you have succeeded, write a sentence or two describing what
is necessary to light a bulb. How many electrical connections are there on the
light bulb?
Here’s a quiz: Predict which bulbs will light and record your predictions.
(You can try the different arrangements if you are unsure.)
2. Now put 3 light bulbs in holders and assemble the following circuits, one after
the other. (Notice that the holders make two different contacts with the bulbs.)
In each case record whether each bulb is bright, dim, or out and explain why.
Keep circuit (d) assembled for further use.
a. b.
# 1 # 1 # 2
14
c. d.
# 1 # 2 # 1
# 2 # 3
3. a) The wires that you are using are very good conductors and have very low
resistance. Using circuit (d), replace a short wire by a very long wire. Do you
see any difference in the brightness of the bulbs? Will changing the length of
any of the connecting wires affect the current in the circuit? Explain.
b) Change the shape of the circuit by gently bending or twisting the long wire
without changing any of the connections. Do you see any difference in the
brightness of the bulbs? Does the shape of the circuit affect the current in the
circuit? Explain.
4. We’ll continue working with circuit (d), which we’ve redrawn below with
some additional labels.
Connect one side of the voltmeter (black post) to point A. Measure and record
the voltage difference between point A and points B, C, D, E, F, G, and H by
connecting the other side of the voltmeter (red post) to each point in turn. At
which points is the voltage the same? At which points is it zero? Explain your
results.
5. Remove bulb # 1 from its holder. What happens to the other bulbs? Explain.
Put bulb # 1 back in its holder and remove # 2. Explain what happens.
6. Short bulb # 2 out of the circuit by connecting a wire from E to F. What
happens to bulb # 2 and # 3? Explain.
15
7. Make a circuit with 1 battery in series with 2 resistors, R1 and R2. Place the
ammeter in the circuit at point A. (To do this, open the circuit at point S, and
connect one wire from the red post of ammeter to the positive end of the
battery and connect black post of ammeter to the left side of R1.) NOTE: In
contrast to a voltmeter, an ammeter is always placed directly in the circuit.
(why?) Measure and record the current through the ammeter (through point
A). Repeat with points B and C. Compare the values at A, B, and C. Does the
current vary from one place to another in a one-loop circuit? (Does current get
“used up” in a resistor?)
8. Design a circuit that allows you to measure the values of R1 and R2
individually, then R1 and R2 in series and parallel. You know the voltage
across a battery and you have ohm’s law to help you! In lecture you learned
that Rseries = R1 + R2 and 21
111
RRRparallel+= . Check your measured values
with there relationships.
9. What would happen to the light bulb when point A is moved closer to point
B? Explain.
16
ELECTRIC VOLTAGE, CURRENT, POWER and WORK
OBJECTIVE:
This experiment is to give you some insight into the meaning of the concept of
electrical voltage and electrical current and how they relate to energy.
It also should reinforce your understanding about the distinction between power
and work.
METHOD:
You will connect a source of electricity to a resistor that is immersed in a water
calorimeter. By measuring the amount of current that flows (number of amperes) and the
voltage decrease (volts) as the current passes through the resistor, you will be able to
calculate the amount of power being dissipated by the resistor.
(Remember that power is the rate of doing work, or in this case, the rate at which energy is beingexpended.)
You will also measure the temperature of the water over a known period of time.
You will make a numerical comparison of the total electrical work done in 2 minutes
intervals to the heat energy required to raise the water temperature in the same time
intervals.
APPARATUS:
Electrical Calorimeter, Ammeter, Voltmeter, Power Supply, Wires, DataStudio,
Computer and Temperature Sensor, Balance and Masses.
THEORY:
To perform this experiment and do the calculations, you’ll need to know the
following:
Thermal Energy - Recall that it takes 1 calorie to raise 1 gram of water 1 degree
centigrade. The net energy increase is the total mass of the water times the number of
degree increase, ΔT, in water temperature:
Q = mΔT, where Q is in calories (1)
Because the water is in a metal cup, this equation must be modified to include the mass
and specific heat of the metal. That is:
17
Q = ( c1 m1 + c2m2 ) ΔT (1a)
where the subscripts refer to the different materials.
Note that heat losses also happen and must be considered! You’ll need to convert
the energy to a different set of units, the joule. There are 4.185 joules in 1 calorie. Both
the joule and calorie are units of energy or work. That is,
Q = 4.185 mΔT, where Q is in joules (1b)
ELECTRICAL UNITS:
You also need to know what the electrical units mean in terms of the fundamental
ideas of work and power.
CURRENT:
One ampere of electrical current means that one coulomb of charge per second is
flowing in the circuit;
1 Ampere = 1 Coulomb/1 sec (2)
VOLTAGE:
One volt means that one joule of energy has been expended on one coulomb of
charge;
1 volt = 1 joule/1 Coulomb (3)
If we multiply the terms in Eqs. (2) and (3), we get
1 Ampere × 1 volt = 1 joule/sec
POWER:
You recognize that a joule per second is the rate of doing work. This is what we
mean by power. Algebraically, we have
P = VI (4)
where V = voltage (volts)
I = current (amps)
P = power which is given the name watts;
18
(A watt is just a different name and means
the same thing as a joule per second)
ENERGY:
The total energy involved in this process is just the power multiplied by the time
the power was on. That is
Energy = Pt (5)
where (E) = joule, (P) = watt, (t) = seconds
SUGGESTED PROCEDURE:
In this experiment, you measure the temperature using temperature sensor with
the DataStudio. Turn on the Interface and Computer and then double click DataStudio
icon. At the “Experiment Setup” window drag the temperature sensor from Sensor List to
analog channel A.
1. Determine the mass of the water you will add to the calorimeter. First weigh
the empty cup and then the cup plus water. Fill 3/4ths full.
2. Connect the DC terminals of the power supply in series with the ammeter and
the terminals on the electrical calorimeter. Also, connect the voltmeter to the
terminals of the calorimeter.
DC- +
power supply
A+ -
V+
-
I
electric
calorimeter
* Don’t turn on the power supply until your instructor has checked your circuit!
3. Measure the initial water temperature with the DataStudio and temperature
sensor.
Click the Start button, wait few second then click Stop button. Drag the
recorded data from Data List to Table Display. Click “Statistics” button on
19
the displayed table window and then choice “Mean”. Manually record the
mean value that is initial temperature of water and calorimeter.
4. Delete the data and table. Double click Temperature Sensor icon to open
“Sensor Properties” window. In Sample Rate choose “Slow”, “30 second”,
then click OK.
5. Click “Options” button to open “Sampling Option” window. Type 600
seconds for Automatic Stop.
6. Drag the Graph Display from Display List to analog channel A.
7. Turn on the DC power supply. Adjust the power supply so that 2 amperes is
flowing in the circuit. Record the voltage and click Start button to begin data
recording.
8. Continue automatically recording the temperature and continue gently stirring
for 10 minutes. Turn off the power supply after stopped data recording.
9. Make graph display window active, click “Scale to fit” button and then click
“Smart Tool” button. Move cross hair to determine the changes of
temperature for every 2 minutes over a total 10 minutes.
CALCULATIONS:
1. Use Eqs. (1a) to calculate the heat energy per time interval needed to raise the water
temperature in your experiment. By using Eqs. (1b), this energy is expressed in joules.
2. Use Eqs. (4) and (5) to find the electrical power and electrical energy in the same time
interval that was dissipated by the resistor in the water calorimeter.
3. Plot the thermal energy as a function of the electrical energy. [That is, electrical energy
on the x - axis and the thermal energy on the y - axis.]
20
Suggest Data Sheet and Calculations
(1). Heat Energy
m1 (mass of water) = _______ (g) c1 (specific heat of water) = _________
m2 ( mass of inner cup & stirrer) = _________ (g)
c2 (specific heat of aluminum) = __________
t
(second)
0 120 240 360 480 600
T
( c° )
ΔT
( c° )
Q = 4.18(c1m1+c2 m2)ΔT
(joule)
(2). Electrical Energy
V = ________ (V) I = __________ (A)
Electrical power P = VI = _________ (j)
t
(second)
120 240 360 480 600
E = Pt
(joule)
21
21
MAGNETIC FIELD
INTRODUCTION:
This lab activity is designed to help you visualize and understand the strength and
orientation of the magnetic fields that occur around current carrying wires. You’ll use the
EM Field Software Program to simulate and draw the magnetic field lines and the field
vectors around:
a. a single wire [carrying current both into and out of the display],
b. a pair of wires,
c. a loosely coupled solenoid, and
d. a tighter solenoid.
CONCEPTS:
This activity will allow you to practice with and lean about:
magnetic field lines
magnetic field vector, Br
, and the
right hand rule
Magnetic Field lines…when a current flows through a wire, a magnetic field
surrounds the wire. The direction of the magnetic field is closed loop around the wire.
How do you know that such a magnetic field exists? Because it exerts a torque on iron
filings, on permanent magnets, and on small magnetic compasses causing them to all line
up with the direction of the field. The magnetic field can also exert forces on any moving
electrical charges.
Magnetic Field Vector, Br
…this is a vector that is tangent to the field lines, i.e. it
indicates a particular direction of the field. The stronger the field, the longer the vector,
B
r. By convention, the field vector direction is given by the “right-hand rule”.
Right-hand Rule…if you point the thumb of your right hand in the direction of
the positive current flow through a straight wire, the direction of the magnetic field points
in the same direction that your fingers curl.
You might ask, is this an arbitrary rule? Could we rewrite the rule? Not really!
Once we defined what “positive charges and positive current flow” meant, that magnetic
field direction is chosen by another arbitrary choice; the direction of the field from a
permanent magnet is said to originate at its N pole and circulate back to its S pole.
Because wires and coils of wire behave like permanent magnets and vice versa, then we
stuck with the “right-hand rule” to make the forces and torque be consistent. To do this
experiment and understand electromagnetism, you can just “remember” and “learn how
to apply” the right-hand rule.
22
About The Program, EM Fields…one of the menu selections is 2D line currents
(magnetism). This menu option allows you to build an arrangement of current-carrying
wires. The wires are to be imagined as very long and perpendicular to the screen. Positive
currents are those flowing out of the screen toward you. Negative currents carry current
into the screen, away from you. The program can then draw in the field lines and
magnetic field vectors for these wires.
PROCEDURE:
Part 1. Single Wire(s)
1. Under the Display menu, choose “show grid”. Then from Sources menu
choose “2D line currents (magnetism)” and place a single, positive current
near the center of the display. Draw field lines at 4 equally spaced distances.
Also put field vectors, Br
tangent to the field lines.
2. Replace the positive current with a negative one.
3. Try changing the increasing the magnitude of the current.
Questions: (a) explain, using the right-hand rule, why the field points in the
directions that it does. (b) Does the magnitude of Br
decrease as 2
1
r
or as r
1?
(c) What effect does the magnitude of the current have on the field…does the
field increase linearly with I?
Part 2. Two Wires
4. Now place two wires on the screen, one carrying current in the (+) direction,
the other in the (-) direction. Separate by two units. Draw field lines and field
vectors.
Questions: (d) Where is the field the strongest? The weakest? (e) Using the right
hand rule, explain why?
Part 3. Coils of Wire
5. Place eight wires on the screen in two rows; 4 positive on the top row, and 4
negative carrying wires on the bottom row. Separate the two rows by three
units. Separate the individual wires by just two units for now. Draw the field
lines, clicking in the space between the two rows. Also draw the field vectors
in
the space between the rows of wires,
the space near the ends, and
the regions exterior to the two rows.
23
6. Add in eight more wires by filling the spaces between the wires so now they
are separated by just 1 unit. Keep the space between the rows the same.
Redraw the field lines and field vectors.
Questions: (f) Where is field the strongest now? (g) Compare the strongest
B
rvector to the case of just a single pair. (h) Explain, again using the right-hand
rule, why the field gets stronger in some regions and almost goes to zero in
others?
24
MAGNETISM and THE TANGENT GALVANOMETER
INTRODUCTION:
This activity is a combined exploration and experiment about the interaction of
magnets and electric currents.
OBJECTIVE:
The purpose of this experiment is to study the effects of an electric current on a
magnet. You will also measure the magnetic field of the Earth.
METHOD:
You’ll use a coil of wire and place a compass at the center of this coil. You’ll
observe that as an electric current passes through the coil, the compass is deflected from
its original north-south alignment. This apparatus can be used to measure the ratio of two
fields; one produced by the current and the other by the earth’s magnetic field.
THEORY and DEFINITIONS:
The strength of a magnetic field, Bv
, at the center of a circular loop of wire is
given by the following equation:
R
NIB
20
µ= (1)
where N = the number of turns in the coil,
R = the radius of the coil in meters,
I = the current through the coil (amperes),
0
µ = 4π×10-7
T⋅m/A, the permeability of free space,
and B is the magnetic field intensity, the unit of B is tesla (T).
A compass needle points in the direction of the magnetic field at the location
where the compass is placed. Consider what would happen if you were to place a
compass at the center of the circular coil with I = 0 and the entire apparatus were oriented
so the compass needle was in the plane of the coil. If a current were now passed through
the coil, the compass needle would deflect through an angle θ. The compass needle will
have rotated until it is parallel with the new magnetic field vector. This new magnetic
field is the vector sum of adding the earth’s Bv
field and the Bv
field from the coil.
If you know either one of these two magnetic fields and the angle between them,
you can calculate the other one. From the diagram you can see that the relationship is
just,
25
earth
coil
B
B=θtan (2)
North
cBv
(coil)
eBv
(Earth’s Bv
(Resultant field)
field)
PROCEDURE:
1. Examine the compass needle and determine the direction of magnetic north.
Also measure the outside diameter of the form on which the coil was wound.
Your coil has 10 turns on it.
2. Position the circular coil on the lab table so that its vertical plane is north and
south. Then support the meter stick through the center of the coil so that it
runs east and west.
3. Put the compass on the meter stick at the center of the coil, and arrange it so
that it reads zero degrees.
4. Connect the coil to the DC output of the power supply and milliameter as
shown in the figure below. Use the 400 mA range of the meter. With no
current flowing, note and record the angle of the compass needle. It should be
zero.
North
Power Supply 10 turns coil
DC output
Compass
ma
20 Ω
resistor
26
5. Increase the current to 50 ma (0.05 a) and record needle deflection (Attempt to
this as accurately as you can. 2 to 2.5 degrees should be your goal.)
6. Repeat for current settings of 100, 200, 300, and 400 ma.
7. Reduce current to zero and reverse the connections to the coil so the current
will pass through in the opposite direction.
8. Take another set of data for the reversed current and needle deflections. Note
the direction of needle deflection obtained in step 5 & 6 to those step 8.
CALCULATIONS:
1. Calculate the absolute average of the pair of angular deflections for equal but
reversed currents.
2. From your electrical current data and the radius of the coil, use equation (1) to
calculate the B field at the center of the coil for each current, Bc.
3. Plot tan θ as function of Bc.
4. Calculate a value for the horizontal component of the earth’s magnetic field. Use
equation (2) and recognize that the slope of the curve you plotted in step 3 is eB
1.
QUESTION:
Suppose the magnetic compass was replaced by a very strong, fixed magnet and
the coil were suspended by a weak spring that allowed some rotation against a restoring
torque. Describe the action when a current is passed through the coil. (This moving coil
configuration is commonly used in electrical meters and galvanometers.)
27
Suggested Data Sheet
Radius of Coil, R = ______ (m); Number of turns, N = _______
CURRENT COMPASS DEFLECTION B FIELD at the CENTER…
I (ma) reverse I (ma) Right Left Aver. Tan θ Bc
+50 -50
+100 -100
+200 -200
+300 -300
+400 -400
Slope of Tan θ vs. Bc = _________ = Be
1
Be = _______ (Tesla)
28
INDUCED EMF
INTRODUCTION:
This activity is combined exploration and experiment about induced
electromotive fore (EMF).
OBJECTIVE:
The purpose of this experiment is to examine how a changing magnetic field can
be used to induce a voltage and cause a current to flow in circuit. You’ll also explore the
concept of what a transformer does and how it works.
METHOD:
In summary you’ll
1. Use a permanent magnet to induce a transient current to flow in long coil of
wire.
2. Induce a current to flow in a secondary coil by changing the current flow in a
primary coil of wire.
3. As an additional exploration, you’ll use a kit to make a lab step-up and a step
down voltage transformer.
PROCEDURE:
Part 1: EMF induced by a moving permanent magnet.
1. Connect the secondary coil, resistance box, and galvanometer in series. [The
secondary coil is the outer coil and has the most number of turns; just set the
inner, primary coil aside temporarily. You’ll need it later.]
Resistance
Secondary Coil
29
2. Set the resistance box to 10,000 ohms.
3. Now thrust the magnet inside the coil. Observe what happens to the
galvanometer needle! When the galvanometer needle moves, what does that
indicate? Change the resistance setting until you get a near full-scale
galvanometer deflection when you insert and then withdraw the magnet.
4. Try varying the speed with which you insert and remove the magnet. Also try
reversing the polarity of the magnet; that is, put the South Pole in first instead
of the North Pole. Record what happens and discuss.
5. Move the magnet up and down with an oscillatory motion and watch the
galvanometer. Vary the frequency of the motion. What kind of current are you
generating with this oscillatory motion?
Part 2. EMF Induced by a Changing Current.
6. Next, connect the primary or inner coil to the dc power supply. Set the
primary coil on the table and adjust the current to 2 Amperes.
7. Pick up the primary coil and insert it (quickly) into the secondary coil. Record
what happens to the galvanometer needle. Explain. Next, place the primary
coil inside the secondary coil with 2 amperes still flowing. Does the
galvanometer show a steady or a transient (temporary) deflection when you
inserted the coil? Explain.
8. Now, open the circuit by removing one of the connecting leads from the
power supply. Record what happens as you open and close the circuit in the
primary coil. Explain.
Secondary
Coil
Primary
Coil
Power
Supply
30
9. With 2 A current through the primary coil and the primary coil sitting inside
the secondary coil, insert the iron rod into the primary coil. Record what
happens to the galvanometer. Explain. Now remove the iron rod and replace
it, this time noting if you can feel any force on the iron rod as you move it in
and out of the coil. Is the force attractive or repulsive?
EXPLORATION: a Simple Transformer Circuit
We’ve set-up a kit that illustrates the major components of transformer. We want
you to see how this transformer can be used to set-up (increase) or set-down (decrease)
an alternating voltage. There are two different coils; one with 200 turns, the other with
800 turns. Both can be placed on a laminated iron core.
We’ve set up an alternating source of voltage that can be connected to either one
of the coils. We want you to measure the voltage on both coils when the oscillator is
connected to one of them. The object is for you to determine how to get the maximum
voltage induced into the second coil!
You can [and should] try:
a. using the coils off the iron core…just move them close to one another,
b. slip the coils on the iron core…leave the cross piece open and,
c. both coils on the closed iron core.
Do these twice: once with the 200 turns coil as input and again with the 800 turns
coil as input.
Describe what you did. Explain how this demonstrates, how a step-up transformer
works.
Transformer Kit
800 turns Laminated
Iron Core
200 turns
31
REFLECTION AND REFRACTION OF LIGHT
OBJECTIVE:
The purpose of this experiment is to study the laws of geometric optics through a
series of hands-on demonstrations. Specifically, you are
1. To trace a laser beam as it reflects from a plane surface,
2. To trace a laser beam as it bends when it enters or leaves a plastic block,
3. To trace a laser beam when total internal reflection occurs, and
4. To determine the focal lengths of mirrors and lenses.
METHOD:
You will have a low power, Helium-Neon laser to use as a light source. The
bright pencil-like beam of the Helium-Neon laser will allow you easily to trace the path
of light rays through various optical components such as prisms, lenses, etc. In this
experiment, the dimensions of the apparatus are large in comparison with the wavelength
of the light. Therefore, the approximation that light travels in straight lines is valid.
APPARATUS:
Helium-Neon Laser, Optical Kit.
THEORY:
A. Reflection
The law of reflection states that when a ray of light is reflected from a smooth
surface the angle i
θ between the incident ray and the normal to the surface is equal to
the angle r
θ between the reflected ray and the normal, as shown in Fig. 1.
iθ =
rθ (1)
32
B. Refraction
If the light crosses the surface and enters another medium, the beam will be bent
at the surface. The law of refraction, called Snell’s Law, specifies the manner in which
the bending occurs:
2211sinsin θθ nn = (2)
where 1θ and
2θ are the angles between the normal to the surface and light ray in
medium 1 and 2. The quantities 1n and
2n are the indices of refraction of the media.
In air, n = 1.0003. In glass, n is in the range 1.4 – 2.0.
As indicated in Fig. 2, Snell’s Law tells us that light is bent toward the normal
when passing into a medium with a greater index of refraction and is bent away from the
normal when passing into a medium with a smaller index of refraction.
PROCEDURE:
CAUTION:
The laser should be handled with caution. Avoid looking directly into the beam.
This is a class II laser and is safe for general lab use. Its power output [less than 1
mw] is low enough to cause no harm to the skin. You should not look directly into
the beam and do not direct the beam into anyone’s eyes.
Experimental Techniques:
You will trace the rays on sheets of computer paper laid on a board. Place the
laser at one end of the board and turn it on. The beam should skim 1-2 mm above the
33
paper. The idea is to keep the beam low so that some of the scattered light will be seen on
the paper, and at the same time high enough so that wrinkles in the paper do not block the
beam.
To take data in this experiment, the following techniques may be helpful.
A. Ray Tracing
1. Put the element where you want it on the paper. Trace its outline and then
don’t move it around on the paper.
2. Each ray is traced by marking two points along each leg of its path (circle the
points - they are data points). After a path is marked, the paper (with the
element fixed on it) is moved to reposition the element with respect to the
laser. This creates a new path, which can then be marked, the paper moved,
etc.
3. When marking is complete, lift the element off the paper and trace the rays by
connecting the dots.
B. Back Reflection
This is a method for aligning a surface perpendicular to the laser beam, and is
handy for drawing normal lines. Position the surface approximately perpendicular to the
beam and look at the reflection of the beam off the end of the laser. When the beam
reflects directly back at the laser, it is perpendicular to the surface.
C. Snell’s Wheel
We have furnished you a device called a Snell’s Wheel. It’s a complete circular
protractor made of plastic. Notice that one-half of the circular disk is solid plastic, while
the other half is open. This design will help you trace and measure the angle of reflection
and angle of refraction of a beam entering or leaving the plastic. It also easily allows you
to see the phenomenon of total internal reflection.
D. Beam Multiplier
Another useful device you’ll use is called a beam multiplier. It’s a block of glass
with parallel face, totally coated with a reflecting material on one side and partially on the
other. When you shine a laser beam a small clear opening, you can get a series of parallel
beam coming out of the partially coated side. This is a practical application of reflection
and refraction phenomena and is very interesting device to study
Experimental Procedure:
Become familiar with the plastic elements and the techniques listed above. Then
do the experimental procedures A, B, C, and D. Procedures A, B, C, and D should each
34
be done on a separate sheet of computer paper. All calculations, results, and conclusions
should be there too.
A. Verify the law of reflection. Using several different angles. You may use a mirrored
surface or a block with a plane face.
B. Determine the index of refraction of a glass cube, using several different angles.
C. Now use the Snell’s Wheel to examine the phenomenon of total internal reflection,
which occurs when the beam of light does not emerge from the plastic, but rather
totally reflects inside.
1. First set up the laser and the wheel as shown in the figures below. Note that you
want the beam to enter the wheel on solid side. Then the beam will emerge from
the plastic into the air.
2. Rotate the wheel as shown in figures (b) and (c). Note what happens to the
reflected beam and the refracted beam. Are the angles of reflection the same as
the angles of incidence? Are the angles of reflection equal to the angles of
refraction? Why not?
3. Continue rotating the wheel until the beam is totally reflected inside the plastic.
[Complete figure (d) above by sketching in the direction of the reflected beam.]
How could you know that total internal reflection happened by looking at the
reflected beam alone? How does the brightness of the reflected beam change
when the refracted beam disappears? Where is the refracted beam at the onset of
total internal reflection?
4. Find the critical angle c
θ (sinc
θ = 1/n) where total internal reflection just begins.
Since you can measure the angle, then you can calculate the index of refraction of
the plastic used in the Snell’s Wheel.
35
D. Examine the effect of a curved mirror on parallel light rays that hit the mirror. Do
both sides of the mirror. Summarize your results, using equation (1). Determine the
focal length of the mirror (the distance from the mirror to the focal point, the point
where parallel rays reflected off the mirror come together or appear to come from).
E. Replace the mirror in part D with the curved plastic lenses, and determine the focal
lengths of these lenses using the same approach as in D.
36
LENSES and OPTICAL INSTRUMENTS
OBJECTIVE:
This experiment is to allow you to study the formation of images formed by single
lens and by lenses used in combination.
METHOD:
You’ll assemble the optical bench with a light source, lens and an imaging screen.
By measuring the distances from source to the lens and from lens to the image you can
calculate the focal lengths of three lenses.
You’ll also combine two lenses on the optical bench to make an “astronomical
telescope”.
THEORY:
The main ideas you’ll need to understand include:
1. The difference between a real and virtual image
2. The thin lens formula
iddf
111
0
+= where 0d = the object distance and
id = the image distance
3. The magnification formula
0
'
d
d
h
hm
i−== where 'h = image height, h = object height and negative
sign signifies that the image is inverted.
4. How to draw a ray diagram
APPARATUS:
Optical bench, light source, image plate, lens holders and 3 lenses (approximate
focal lengths of 5, 18 and 37 cm).
NOTE: Please handle lenses at the edges to avoid smudging or scratching.
37
PROCEDURE:
Part 1. Focal length of single lenses and real images.
1. In this part, test one lens at a time. Set up the optical bench as shown in the figure.
Begin with the 18 cm focal length lens.
screen
lens
light source
optical bench wall
(So how do you know which lens is which? You can get a rough idea of the
approximate focal length by either of two methods. Look through the lens at a
distant object (at least 3 meters away). Vary the distance between you eye and the
lens. There will be a transition zone where the object is neither inverted nor erect,
but seems to fill the entire lens. At that point, you eye is in the approximate focal
plane of the lens. Another way is to form a real, inverted image of a distant object
on any reflecting surface. The distance from the lens to the surface is the
approximate focal length. The more distant the object, the better these methods
are.)
2. Now, back to the optical bench! Adjust the distance from the source (the object)
to the screen to 1 meter. Put the 18 cm lens in the holder and adjust its position
until you get a sharp image of the light source. Measure the object and image
distances from the lens. Also measure the object and image sizes. Calculate the
focal length of the lens using the thin lens formula. Compare the measured
magnification with the calculated value. Draw a ray diagram that shows the
situation you just observed. Try to make it roughly to scale.
3. Repeat using the 18 cm lens, but this time find a different position for the lens that
gives another sharp image on the screen. Explain why the image size is different
now than it was in step 2. Draw a ray diagram for this arrangement.
4. Place the light source 10 cm from the lens. Can you get an image on the screen?
Look through the lens at the object. What do you see? Explain with words and a
ray diagram.
38
5. Repeat step 2 for the 37 cm and 5 cm lenses. (The image for the 37 cm lenses will
be off the end of the optical bench. Using the white laboratory wall as a screen.
Adjust the bench to a convenient distance from the bench to the wall to make it
easy for you to measure the image distance.)
Part 2. Astronomical Telescope.
1. In this part of the experiment, you’ll assemble an astronomical telescope using
two lenses, a 37 cm and a 5 cm lens. Use the 37 cm lens for the objective and the
5 cm as the eyepiece.
2. Place a light source on the far side of the lab, at least 3 meters away. Form a real
image on the screen using the 37 cm lens. (Record the distance from the lens to
the screen.) Now place the eyepiece, 5 cm lens, behind the screen at a distance
approximately equal to its focal length. Remove the screen. Look through the
eyepiece and adjust the lens to get a sharp image of the distant object. Record the
distances. Turn on the room lights and look through your “telescope”. Describe
what you see. Alternately, take your telescope into the hallway and look at distant
objects at the far end.
screen
light source 37 cm lens 5 cm lens
eye
39
PHYSICAL OPTICS
OBJECTIVE:
The purpose of this experiment is to study the phenomena of physical optics
through a series of hands-on demonstrations of optical interference and diffraction
phenomena.
METHOD:
You will use a low power, Helium-Neon laser as a light source. The coherent and
monochromatic beam of the Helium-Neon laser will allow you to easily observe
interference and diffraction through slits and diffraction gratings. In this experiment,
certain dimensions of the apparatus are small in comparison with the wavelength of light.
Therefore, you will be able observe the effects of the wave nature of light.
APPARATUS:
Helium-Neon Laser, Optical Kits.
THEORY:
Important equations are:
λθ ma =sin for maxima for double slits and diffraction grating
λθ mD =sin for minima for single slit
DETAILED PROCEDURE:
CAUTION
Avoid looking directly into the laser beam. This laser is safe for general lab and
industrial use. Its power is low enough to case no harm to the skin. You should prevent
the direct beam from striking your retina, as you would avoid any intense source of light.
Part 1. Diffraction: knife-edge
Although at one time, people believed that light traveled in perfectly straight
lines, we can use the laser to see that light actually bends, or is diffracted, around small
objects.
1. Set up the laser so that it is aimed at a screen about two meters away.
40
2. Slide the edge of a razor blade part way into the laser beam using the
magnetized razor blade holder and observe the interference patterns on the
screen.
3. Make a sketch of the pattern you see. Close observation will show that there is
not a sharp shadow of the edge of the razor blade on the screen, but instead
there is a diffraction pattern consisting of a series of bright and dark fringes
parallel to the edge of the razor blade.
4. Why does this pattern appear the way it does? What physical phenomenon is
responsible for this pattern? Is light acting as a wave or as a particle now?
Explain.
Part 2. Single Slit
In this section of the experiment we will use a single slit which is nothing more
than two knife-edges placed close to each other. We will observe how slit width affects
the diffraction pattern and we will measure the thickness of a sheet of paper using our
newfound knowledge of diffraction through slits.
1. Use the same set-up as for part one above, but now attach a second razor blade
into the magnetized holder so that the two blade edges are parallel and facing
each other. Observe the diffraction pattern as you push the blades together.
2. How does the diffraction pattern change as the blades are moved together or
apart?
41
3. You will now measure the thickness of a sheet of paper
a. Insert a stack of two sheets of paper in between the razor blades and press the
blades together.
b. Carefully slide the paper out from between the blades while holding the blades
together.
c. Put this razor blade slit in the path of the laser beam and measure the distance
from the slit to the screen (it should be about two meters). Call this distance L.
d. Measure the distance from the center of the central bright fringe to the center
of the first black minimum on the left side. Call this distance XL.
e. Measure the distance from the center of the central bright fringe to the center
of the first black minimum on the right side. Call this distance XR.
4. Calculate the values for width of the slit, D1 and D2 by using the equation
given above. Remember that θ is measured from the center of the central
maximum to the first minimum. Since angles are small, you can use: sinθ =
tanθ = X/L. λ is the wavelength of the laser. λ = 710328.6
−× meter.
5. Calculate the mean value of D1 and D2 . What is the thickness of a sheet of
paper? (Remember the double thickness of a sheet of paper is equal the width
of slit, D.)
Suggested data table:
L XL XR D1 D2 D
42
Part 3. Interference: Double Slits
When the laser beam is sent through two equal, narrow, parallel slits, each slit
produces an identical diffraction pattern. If the slits are close enough together, the
diffraction patterns overlap and interference occurs. In this part of the experiment we will
observe double- slit diffraction and examine the characteristic diffraction and interference
patterns produced as the slit widths and spacing are varied. You will use a diffraction
slide, which has 4 pairs of double slits on the lower half of the slide. (It also has 3
diffraction gratings on the upper half of the slide.)
1. Place the diffraction slide mosaic in front of the laser so that the beam is
transmitted through the first of the four sets of double slits. The first set of
double slits is labeled 25u×25u . The distance between the slits, a , is
approximately 4.5 ×10-5
meter.
2. Observe the diffraction pattern that appears on a screen two meters from the
slits. Sketch the diffraction pattern. And measure the distance (XL) from
center of the central maximum to the center of first maximum on the left side.
Measure the distance (XR) from center of the central maximum to the center
of first maximum on the right side.
3. Repeat step 1-2 above, but this time using the second set of slits (labeled
25u×35u). These slits have same width as the first set but their separation, a ,
is approximately 5.8 ×10-5
meter. Compare this diffraction pattern with the
diffraction pattern due to the first set of slits.
43
4. Repeat step 1-2 above, but this time using third set of slits (labeled 25u×50u).
The separation, a , is approximately 7.5 ×10-5
meter. Compare this pattern
with those produced by the first and second sets of slits.
5. Considering the findings and observations you made in steps 1-4, predict the
resultant diffraction pattern of the fourth pair of slits (labeled 50u×50u). Slit
width is twice that of the others and separation, a , is approximately
10.0 ×10-5
meter. Write your prediction.
6. Use the laser to see how accurate your guess was. Explain what happened
(How close was your guess? What went wrong? Did you see anything
unexpected?).
7. Calculate the exact separations, a , for each set. To do this you will use the
equation: λθ ma =sin , where m=1, sinθ = tanθ = X/L. X is the mean value
of XL and XR. L is 2 meters.
Part 4. Diffraction Gratings
When the laser beam is transmitted through a series of narrow evenly spaced
parallel slits that are spaced close together, a much brighter pattern of fringes is observed
than those due to a double-slit set-up. An extended series of slits is called a diffraction
grating. In this part of the experiment, the diffraction and interference patterns produced
by three diffraction gratings will be investigated. The diffraction gratings are on the upper
part of the mosaic slide. Because photographic film shrinks during processing, all of the
line spaces given in the instructions below are to be taken as approximate values.
44
1. Attach the diffraction grating to the magnetic holder at two meters away from
screen. Align it so that the laser beam does through the diffraction grating
with 25 lines/mm. Walk close to the screen and observe the diffraction
pattern.
2. Make a sketch of the diffraction pattern and compare this pattern with the
patterns for double-slits. Measure the distance (XL) from center of the central
maximum to the center of first maximum on the left side. Measure the
distance (XR) from center of the central maximum to the center of first
maximum on the right side. Calculate the mean value, X, for XL and XR.
3. Repeat steps 1-2 for the diffraction grating with 50 lines/mm.
4. Repeat steps 1-2 for the diffraction grating with 100 lines/mm.
5. Calculate the actual number of lines per mm for each grating. To do this we
will again use the following equation, λθ ma =sin . Now a is the separation
between the lines on the grating.
Remember that [#lines/mm] = [1/a ] for a measured in mm.
45
ATOMIC SPECTRA
OBJECTIVE:
The basic objective of this experiment is to observe and measure the wavelength
of discrete lines in the Hydrogen and Mercury spectrum. You’ll also observe a
continuous spectrum from an incandescent light source. To do this, you will assemble
and use a simple grating spectroscope.
Another objective of this experiment is to understand how the Bohr theory of the
atom is related to the Hydrogen spectrum.
METHOD:
The grating constant must be obtained from a calibration using a spectral line of
known wavelength. Satisfactory results can be obtained by using a Helium Neon laser,
632.8 nm, as a known calibration source.
You will do the following:
a. Calibrate the grating using a Helium-Neon laser
b. Measure three lines in the hydrogen spectrum
c. Observe the mercury spectrum and measure the green line
d. Observe a spectrum from a hot, incandescent body
APPARATUS:
Transmission diffraction grating, grating holder, mercury discharge tube,
hydrogen discharge tube, power supplies and He-Ne laser.
THEORY OF THE SPECTROMETER:
A simple grating spectrometer.
The diffraction grating can be used to disperse light from a source into its
wavelength components. The simple apparatus you’ll use today will allow you to see the
entire spectrum at once. With some care and assistance from your lab partner you’ll be
able to measure the angle each color is diffracted. Professional and research instruments
are constructed that work on this same general principle. They measure the angles far
more accurately than you will today.
46
The wavelength can be calculated from the angle of diffraction. The grating needs
to be approximately perpendicular to the incident beam. Then
θλ sindn = (1)
where n = the order, λ = wavelength, d = grating constant, and θ = the left or right
angular deflection.
Measuring the angle can be done as shown in the illustration. When you look
through the grating in the direction of the light source, several things can be seen. First,
of course will be the source itself. You’ll also be able to see a series of images of the
source to the right [and left]. Notice that these images are of different colors. Your
partner will need to help you locate the apparent positions of these images along the
meter stick. Then the diffraction angle is found from the equation
tanθ = X/L (2)
where X = the distance between the image and source [along the meter stick] and
L = the distance from the source to the image.
[Note: θ is not small, so the small angle approximation won’t work!]
ATOMIC SPECTRA AND BOHR THEORY OF THE ELECTRON
Another objective of this experiment is to compare your measured spectrum for
hydrogen to the prediction of the Bohr theory of the hydrogen atom.
Neils Bohr developed a planetary-type model of the hydrogen atom to explain its
spectrum. In this model electrons move in circular orbits around the nucleus (proton). He
postulated that only orbits with special radii were allowed, each orbit having a different
value for the electron energy. The lines that were observed in the spectrum of hydrogen
atom were assumed to be light (photons) emitted by electrons changing from one discrete
energy level to another. The energy of the levels in Bohr’s model is:
47
E1 = -21
6.13 ev, E2 = -
22
6.13 ev, E3 = -
23
6.13 ev, En = -
2
6.13
n
ev, etc.
Bohr postulated that when an electron goes from a higher energy orbit to a lower energy
orbit, it emits a photon. To conserve energy, the change in the electron’s energy,
ΔEelectron = Ephoton . The energy of a photon is related to its wavelength by
Ephoton = hf = hc/λ photon . Therefore, when an electron goes from its 3rd
energy level to its
2nd
energy level,
E3 – E2 = Ephoton
or - 23
6.13 ev – (-
22
6.13 ev) = 6.242 18
10× (hc/λ photon) ev (3)
Electrons that end up in the 2nd energy level emit all of the lines of the hydrogen
spectrum that you can see directly with your eyes.
DETAILED PROCEDURE:
Part 1. Grating Calibration
1. Shine the red laser light through the grating so that it lands on the center of the
meter stick, and observe the series of red spots that are both to the right and
left of the central image. [Don’t look directly into the laser beam!]
2. Carefully measure the diffraction angle for the first spot to the right. Do this
by measuring the distance to the screen and the distance from the central
image. You will have to work with a partner to accomplish this. Use equation
2 to determine θ .
3. After you’ve found the angle, then use this angle and the wavelength of the
laser in equation 1 to calculate the value for the grating constant, d. Repeat
this measurement for the first spot on the left. Take an average value of your
results and use this in the rest of the experiment.
Part 2. Measurement of the Hydrogen Spectra
1. Position the hydrogen source at the 50 cm mark of the meter stick. Look
through the grating and observe the series of images. Describe what you see to
the right and left of the source.
2. Locate three different color images along the meter stick and record their
positions as accurately as you can. Also, carefully measure the distance, L,
from the grating to the meter stick. Now use equation 2 to calculate the three
angles of diffraction for each color image.
48
3. Use equation 1 to calculate the wavelengths. Use the value of d, the grating
constant you found in part 1. Repeat your measurement using the spectral
lines on the other side.
4. Compare the average values of each of your sets of measurements with the
accepted value of 435.05, 486.13, and 656.28 nm. How accurate were your
measurements? What is the main source of any discrepancy?
5. Calculate the energy of the photons in the red light. Compare this to E3 – E2
for the electron. Repeat for the photons in the other colored lines. Compare
with E4 – E2 and E5 – E2. Does Bohr’s theory work?
Part 3. Measurement of a Mercury Green Line
1. Replace the hydrogen source with a mercury discharge lamp. Describe what
you see when you look through the grating. Are the colors the same? Do you
think that you could determine the type of atom by looking at its spectrum?
2. Measure the wavelength of the green line of mercury using the same
technique you used for hydrogen.
Part 4. Observe a Continuous Spectrum
1. Replace the mercury source with an incandescent lamp. Recall that tungsten
or other incandescent lamp has a small filament of wire, which is electrically
heated until it is hot enough to emit light. The light that you see is emitted
from a solid material rather than individual atoms.
2. Describe what you see now. How does it differ from your previous results?
What do you think cause the difference?
49
Suggested Data Sheet
Part 1. Grating Calibration
L = __________ (cm) X = __________ (cm)
tanθ = X/L = _______ θ = _______
grating constant θ
λ
sin=d =
Part 2. Hydrogen Spectra
Violet Line
L = ______ (cm) X = ________ (cm)
tanθ = θ =
Blue Line
L = ______ (cm) X = ________ (cm)
tanθ = θ =
Red Line
L = ______ (cm) X = ________ (cm)
tanθ = θ =
50
PHOTOELECTRIC EFFECT
OBJECTIVE:
The major objective is for you to understand how the quantization of light
explains the photoelectric effect.
METHOD:
1. You will look the changes of current that flows through a vacuum phototube
as the changes of the voltage applied between the anode and cathode. This
will be done for two different light levels using the same color light. Also you
will see they have same voltage needed to stop the photocurrent.
2. You will illuminate the phototube with different colors of monochromatic
light and measure the amount of voltage needed to stop the photocurrent.
From this information you will calculate a value of Planck’s constant.
APPARATUS:
Photoelectric Effect Module, digital voltmeter, mercury arc light, laser and three
spectral filters.
The Photoelectric Effect Module consists of a 1P39 vacuum photodiode, a
variable voltage supply that is applied to phototube, and a high gain amplifier and meter
to read the current that flows through the phototube. Measurements are made of the
photocurrent as a function of voltage that is applied across the photodiode. When light
falls on the phototube surface, electrons are emitted and current can flow depending on
the magnitude and polarity of the applied voltage.
THEORY:
In the latter part of the 19th
century, experiments showed that, when light is
incident on certain metallic surfaces, electrons are emitted from the surfaces. This
phenomenon is known as the photoelectric effect, and the emitted electrons are called
photoelectrons.
Several features of the photoelectric effect could not be explained with classical
physics or with the wave theory of light. The major observations that were not
understood are as follows:
1. No electrons are emitted if the incident light frequency falls below some
cutoff frequency, fc , which is characteristic of the material being illuminated.
This is inconsistent with the wave theory, which predicts that the photoelectric
effect should occur at any frequency, provided the light intensity is high
enough.
2. If the light frequency exceeds the cutoff frequency, a photoelectric effect is
observed and the number of photoelectrons emitted is proportional to the light
51
intensity. However, the maximum kinetic energy of the photoelectrons is
independent of light intensity, a fact that cannot be explained by the concepts
of classical physics.
3. The maximum kinetic energy of the photoelectrons increases with increasing
light frequency.
4. Electrons are emitted from the surface almost instantaneously, even at low
light intensity.
A successful explanation of the photoelectric effect was given by Einstein in
1905. He assumed that light (or any electromagnetic wave) of frequency f can considered
a stream of photons. Each photon has an energy E, given by E = hf, where h is Planck’s
constant.
Einstein showed that the maximum kinetic energy, Kmax, of the electrons emitted
from a surface is
Kmax = hf - Φ , (1)
Where Φ is the work function of surface, h is Planck’s constant (h = 6.63 x 10-34
js), f is
frequency of the light and Kmax = eVs, where Vs is stopping voltage and e is the charge of
the electron.
Equation 1 can be rearranged to
eVs = hf - Φ . (2)
METHOD:
The apparatus that you’ll use to study the photoelectric effect and measure
Planck’s constant is shown in simplified form in the drawing below:
52
Light strikes the curved surface of the vacuum tube photocathode. If the
wavelength is short enough, electrons are emitted from the surface of the cathode. If the
anode post were made positive, then the electrons would be attracted to the positive
terminal and current would flow in the circuit shown.
In this apparatus, we want to stop the flow of electrons, so the anode is made
negative to stop the electron flow. The apparatus allows you to adjust the magnitude of
the voltage that will just stop the photocurrent from flowing. The current detector internal
to this apparatus has a sensitivity of approximately 1 nanoampere. When the photocurrent
has been stopped, then the stopping voltage is measured with an external voltmeter.
PROCEDURE:
1. Cover the aperture of the photoelectric module with an opaque card. Then adjust
the zero control for zero meter reading. Also adjust the voltage adjustment to read
zero on the DVM.
2. Replace the opaque card with a blue filter. Turn on the mercury lamp and position
it 4 to 6 inches from the phototube. CAUTION! DO NOT look directly into the
mercury lamp! Get the maximum reading you can on the meter.
3. Without disturbing the position of the lamp, increase the anode voltage. Record
the voltage when the photocurrent reaches zero. That is stopping voltage. NOTE:
Once the photocurrent reaches a zero value, further increases in the anode voltage
have no effect on the current because it has all been stopped…so don’t “pass” the
voltage that corresponds to the zero current!...Note also that you can check the
zero point by placing the opaque card in front of the detector opening, if the
reading on the meter does not drop, then you are at the zero point.
4. Set the anode voltage to zero. Reposition the lamp further away so that the
photocurrent is _ of what is was in step 2. Then repeat step 3.
5. Repeat steps 2-3 using mercury lamp with green filter.
6. Repeat steps 2-3 using laser with red filter.
The colored filters are used to isolate the spectral lines and help stray room light.
The filter-source combinations you’ll be using are:
Mercury with blue filter f = 7.1 x 1014
Hz
Mercury with green filter f = 5.5 x 1014
Hz
Laser with red filter f = 4.7 x 1014
Hz
53
QUESTIONS:
1. How does your data for two levels of blue light show that the stopping voltage is
independent of the intensity of the light? Discuss.
2. Explain why the blue light required a larger negative stopping voltage than the
green light, and the green light required more stopping voltage than the red light.
CALCULATIONS:
1. Plot the stopping voltage vs. frequency using three data points of blue light, green
light and red light, and draw the best straight line you can through the points.
(Plot Vs on the y-axis and f on the x-axis. Don’t connect the dots – your best-fit
line may not touch any of the three data points).
2. Find slope from your graph. The slope should equal e
h. Calculate a value for
Planck’s constant, h. (e = 1.6 x 10-19
C is electron charge).
3. Compare your result to the accepted value for Planck’s constant.
4. Calculate an approximate value for Φ, the work function of the metal. Hint: just
extend the line on your graph and find the approximate x-intercept. The x-
intercept should equal Φ/e.
APPENDICES
A-1 Graphical Presentation of Data
A-2 Summary of Error Analysis
GRAPHICAL PRESENTATION OF DATA
INTRODUCTION
Good graphs often convey the essence and meaning of an experiment. One of the
most important skills you will use in your physics labs is plotting and interpreting graphs.
RULES for GRAPHING
The basic rules for graphing are summarized here and illustrated in the graph
shown below. With a little practice, these rules will become automatic when you graph
your data in lab.
1. Use words to title every graph.
2. Label the axes to show what is being plotted and what the units are.
3. Graphs should cover as much of a page in your notebook as possible.
4. Convenient scales should be selected to make it easy to plot and read numbers
on the graphs. For example, scale divisions of 0.1 sec. are better than 0.15 sec.
5. By convention, the variable that you control is usually plotted on the x-axis.
6. If the points on the graph appear to lie on a straight line, draw the best straight
line through the points (the one that passes as close to as many points as
possible). If the points do not appear to lie on a straight line, draw a smooth
curve that passes as close to as many data points as possible.
7. If the data points being plotted has an associated error or uncertainty this can
be graphically represented by error bars. An error bar is a line through the data
point with a length corresponding to the value.
8. Always place borders (small circle or square) around the data points.
GRAPHICAL ANALYSIS
If a graph yields a straight line, the quantities graphed have a linear relationship.
This mean that one variable is directly proportional to the other variable, and a simple
equation for this can be written: bmxy += . Graphs of this type are very useful: it is easy
to find the values between data points (interpolation), and the line can be extended to find
points outside the data range (extrapolation).
A linear graph has a constant slope (steepness). In the general equation for such a
line ( bmxy += ), the slope is m . The slope can be either a positive or a negative
number. If m is positive, the line slopes uphill. That is, y increases as x increases. If m
is negative, the line slopes downhill, and y decreases as x increases. The quantity b is
called the y -intercept. This is the value of y where the line intersects the y -axis. That
is, b is the value of y when x = 0.
Applying this discussion to the above graph of velocity vs. time, we note that the
graph is linear and the slope is positive. The equation that relates velocity to time ( y -axis
to the x -axis) is 0vatv += . The slope, a , can be calculated from the graph, and the y -
intercept, 0v , can be taken from the graph. This is illustrated below. For good accuracy,
always measure the slope over as wide a range of xΔ and yΔ as possible. It is best to do
the slope calculation on the graph as shown.
Many of the experiments will use this kind of graphical analysis to determine
physical quantities. As you will learn in class, the slope of this line, a , corresponds to the
acceleration of the cart, and the y -intercept, 0v , is the initial velocity of the cart.
SUMMARY OF ERROR ANALYSIS
Every experimental quantity has an uncertainty: an estimate of how much you
might reasonably expect the measured value to differ from the true value. This can be due
to inaccuracy of the measuring instruments, difficulty in reading between scale divisions,
human errors such as inconsistent reaction times, and many other causes. When
comparing two numbers or determining an unknown, it is important to consider the
degree of uncertainty, or error, that you think exists. You should always estimate and
record the uncertainty in every measurement you make. Some rules for estimating
uncertainty are summarized here.
Unfortunately, in data analysis the terms uncertainty and error are practically
synonymous. Although “uncertainty” is less ambiguous, “error” is more commonly used
in the literature. In this lab, we will largely conform to the accepted usage, but you should
remind yourself now and again that “error” does not mean “mistake” -- it means
“uncertainty”. The uncertainty can be expressed in two ways: Absolute Error and
Relative Error.
A. Absolute Error
This is an estimate of how much a measured quantity may differ from the true
value, expressed in the same units.
For example, if you measure a length l as 50.0 cm and you think it is accurate
within 2 mm ( lΔ = 0.2 cm), then the length is expressed with the absolute error as
l = 50.0 ± 0.2 cm
B. Relative Error
This is the radio of the absolute error to the measured quantity, often expressed as
a percentage:
R. E. = %100×Δ
x
x
In the example above,
R. E. = %100×Δ
l
l = %100
0.50
2.0×
cm
cm = 0.4%
and the length is then expressed as
l = 50.0 ± 0.4%
C. Significant Figures
After an uncertainty has been assigned to quantity, it is important that the quantity
itself be specified only to this limit of accuracy. This is accomplished in writing l = 50.0
± 0.2 cm since both the length and the uncertainty are given to tenths of a centimeter. It
would be meaningless to specify l more exactly, such as l = 50.003 ± 0.2 cm, because
the uncertainty is in the lengths place and thus nothing is known about the thousandths
place. On the other hand, if the length is written as l = 50 ± 0.2 cm, accuracy is lost
because you can’t assume that 50 cm is the same as 50.0 cm (49.6 cm would round off to
50 cm, as would 50.4 cm). Thus, the three figures 50.0 are significant and are kept; all
others are insignificant and are dropped.
D. Accuracy of Repeated Measurements
Sometimes it is difficult to determine the best value of a quantity from one
measurement, as in measuring a time interval with a stop clock when your reaction time
can introduce an error. In these cases, it is useful to make several measurements and
apply the following rules:
RULES FOR ACCURACY OF REPEATED MEASUREMENTS
1. The average value is the best answer.
2. The uncertainty is estimated by finding a range that contains most or all of the
readings.
For example, if the time of an event is measured repeatedly:
time (sec)
2.02
2.14
1.92
1.82
2.08
1.92
2.18
2.00
2.06
1.96
The average of these times is
t = 2.01 sec.
The standard deviation, N
σ , is given by
( )
N
xx
N
i
i
N
∑=
−
= 1
2
σ
and for this data σ = 0.10 sec. So that, 70 % of the readings fall within the range
(2.01 – 0.10) < t < (2.01 + 0.10). The time is then expressed as
t = 2.01 ± 0.10 sec.
or, as a relative error,
t = 2.01 sec. ± 5%
E. Uncertainty in Scale Readings
If a measurement does not line up exactly with a scale marking, it is necessary to
interpolate: estimate the position between scale markings. When using scales with
marking close together, like mm markings on a meter stick, it is common to read to the
nearest division and estimate the uncertainty as 2
1 of the scale division, such as 36.0 ±
0.5 mm. On scales with wider markings, it may be possible to interpolate more
accurately, such as measuring t = 23.6 ± 0.2 sec. with the stop clock.
Different observers might disagree on the precise size of the uncertainty;
determine for yourself what you consider a reasonable estimate of this range.
As with other techniques of error analysis, this must be used with judgement. For
example, in section D above where the range is ± 0.02 sec., then this uncertainty can be
ignored since it is much smaller than the uncertainty due to repeated measurements.
F. Accuracy of Graphical Results
When you construct a graph you make a judgement as to what constitutes the
best-fit line through the data points, since all the points are not on the line. Thus, there is
a question of accuracy since you probably don’t draw the “absolute” best line. An
estimate of the uncertainty is obtained from one of these two methods:
RULES FOR ACCURACY OF GRAPHICAL RESULTS
1a. Have you and your partner make independent graphs of the same data. Take
the difference between the slope values as the absolute error.
OR
1b. If you’re working by yourself, draw another “best-fit” line that differs from
the first. But still fits the data. Again, take the difference in the slopes as the
uncertainty.
G. Discrepancy
Experiments often conclude with a comparison of experimental and theoretical
results. The two are rarely exactly the same, so you have to decide if they are in
reasonable agreement. To do this, find the discrepancy (the difference between the two
numbers) and compare it to the uncertainty of both numbers.
This is a general method of determining the validity of experimental results and
can be used in all experiments, in physics and elsewhere that involves the comparison of
two numbers.
The discrepancy is expressed as an absolute number or a percentage. For example,
if two accelerations are:
aex = 42.5 cm/sec2
and
ath = 42.8 cm/sec2
then the absolute discrepancy is
0.3 cm/ sec2
or, expressing it as a percentage, the relative discrepancy is
%7.0%100 =×−
th
exth
a
aa
Without further analysis, the discrepancy tells you a lot about your experiment. If
it is very small, like 0.1%, then the agreement is very good and you also are lucky, since
this is about the limit of accuracy of most of the measuring equipment. If it is around 1%,
you can probably find an explanation by carefully looking at the uncertainties that
randomly appear in the experiment. If it is large, like 10%, then you can strongly suspect
a gross error, which is almost always human (i. e., yours).
H. Putting It All Together
Which is bigger, your discrepancy or your uncertainties? If your uncertainties are
larger, you can say with some confidence that the theory is justified.
If the discrepancy is larger, then you cannot claim that the theory is verified.
However, don’t jump to a rash conclusion that the theory is wrong. Instead, first check
your work to make sure you didn’t make a mistake. If not, then consider systematic errors
that could affect the results. Remember, the uncertainties that you determine are estimates
of random errors. Uncertainties do not reflect systematic errors such as friction or a
consistent mismeasurement of a quantity.
If you suspect a particular systematic error is present, relate it to the experimental
findings. For example, in an air track experiment, if the measured acceleration aex is
lower than predicted by theory, you could hypothesize that this was due to friction. On
the other hand if aex is higher than ath, friction would not be a reasonable explanation, but
a recheck of the levelness of the track or the value of the mass might lead to something.
Your results are always meaningful if you think about the physics of the experiments.